Visualization system

ABSTRACT

A visualization system includes a surgical microscope assembly for viewing a surgical region under magnification. The surgical microscope assembly is provided with a computer unit having a display for displaying image data. A detection arrangement is configured to detect endoscopic images in the surgical region and is operatively coupled to the surgical microscope assembly. A circuit actuable by a viewing person is configured to detect actuation data. The circuit is configured to set an operating state of the surgical microscope assembly matched to the detection arrangement in response to a presence of the actuation data for the surgical microscope assembly.

CROSS REFERENCE TO RELATED APPLICATION

This application claims priority of German patent application no. 10 2015 202 605.1, filed Feb. 12, 2015, the entire content of which is incorporated herein by reference.

FIELD OF THE INVENTION

The invention relates to a visualization system with a surgical microscope for observing a surgical region with magnification, containing a computer unit with a display for displaying image data, and with a device for acquiring endoscopic image data in the surgical region, which is operably coupled to the surgical microscope for displaying the endoscopic image data. Moreover, the invention relates to a method for operating a visualization system with a surgical microscope and with a device for acquiring endoscopic images.

BACKGROUND OF THE INVENTION

U.S. Pat. No. 6,398,721 B1 has disclosed such a visualization system. Described therein is a surgical microscope which has a microscope unit which is held on a stand and which contains optical assemblies for observing a surgical region under magnification with an optical observation beam path. The visualization system has an endoscopic examination device, which may be embodied as a video endoscope, which can be connected to the surgical microscope by way of electrical contacts formed in the microscope unit.

United States patent application publication 2005/0020876 A1 discloses a visualization system with a surgical microscope which has a microscope unit, in which endoscopic image data can be displayed. For the purposes of acquiring the endoscopic image data, there is an endoscope received at a stand device in this visualization system. The position of the endoscope relative to the microscope can be referenced at the stand. This enables visualization of endoscope images in the observation image of the operating system with the correct location and position.

SUMMARY OF THE INVENTION

It is an object of the invention to provide a visualization system and a method for operating a surgical visualization system wherein a display of endoscopic images to a viewing person is made possible in an ergonomically advantageous manner during a surgical procedure.

In the present case, a surgical microscope is understood to mean a system with a microscope unit, preferably embodied as a stereo microscope, which is received at a stand and which enables an observing person to observe a surgical region with magnification. The microscope unit can be configured for visualizing the surgical region with an optical observation beam path. However, it is also possible to provide a microscope unit which brings digitally acquired images to the display for an observing person. An example of a surgical microscope within the meaning of the invention is the OPMI® Pentero® system, manufactured and distributed by Carl Zeiss Meditec AG.

An endoscope within the meaning of the invention is an optical instrument for observing and examining body cavities. Endoscopes within the meaning of the invention have an endoscope body preferably extended in a longitudinal direction. The invention understands a video endoscope to be an endoscope which enables the digital visualization of body cavities. Video endoscopes contain a device for imaging a surgical region on an image sensor. Within the meaning of this invention, endoscopic image data are image data acquired by way of a video endoscope.

The invention proposes that the visualization system contains a circuit which is configured for acquiring actuation information and actuatable by an observing person, the circuit setting a surgical microscope operating state matched to the device for acquiring endoscopic images in the surgical region when the actuation information for the surgical microscope is present.

By way of example, the circuit can be arranged wholly or partly in the device for acquiring endoscopic images in the surgical region.

A surgical microscope operating state matched to the device for acquiring endoscopic images in the surgical region can consist of, for example, a specific setting of a system for setting the magnification of the observation image of the surgical microscope (magnification system), a specific setting of an illumination system which provides illumination light for illuminating the object region of the surgical microscope, or of a specific setting of filters in an illumination beam path and/or in an observation beam path of the surgical microscope, or else of a specific configuration of a display of the surgical microscope.

Here, the circuit can be an activation circuit which brings the device for acquiring the endoscopic images from a rest state into an activation state and which contains an activation sensor.

Here, a concept of the invention is to embody the activation sensor as a sensor from the group containing gyro sensor, Hall sensor, touch sensor or speech sensor.

According to the invention, it is proposed that the device for acquiring endoscopic images in the surgical region has at least one endoscope. In this case, the activation sensor is preferably arranged in an endoscope body of the endoscope. However, it is noted that the activation sensor can also be arranged in the surgical microscope itself.

A concept of the invention is that the device for acquiring endoscopic images in the surgical region contains at least one endoscope, which, in a first operating state, enables the examination of white light scattered in the surgical region and which, in a further endoscope operating state differing from the first operating state, enables the examination of fluorescence light in a defined wavelength range of a dye, such as 5-ALA, sodium fluorescein (NaFl) or else indocyanine green (ICG), excited to fluoresce in the surgical region and/or the examination of autofluorescence light in the defined wavelength range of biological tissue and/or objects in the surgical region.

The dye 5-ALA is excited to fluoresce with, for example, light with a wavelength of 400 nm≦λ≦410 nm. Then, 620 nm ≦λ≦710 nm applies for the wavelength λ of the fluorescence light. The dye NaFl is excited to fluoresce with light with a wavelength of 460 nm≦λ≦500 nm. In the process, fluorescence light in the wavelength range of 540 nm≦λ≦690 nm is generated. In order to excite the dye ICG to fluoresce, the latter must be impinged by light with a wavelength of 700 nm≦λ≦780 nm. The wavelength λ of the emitted fluorescence light then lies in the wavelength range of 820 nm≦λ≦900 nm.

It is also a concept of the invention that the surgical microscope, in a first surgical microscope operating state, enables the examination of white light scattered in the surgical region and, in a further surgical microscope operating state differing from the first operating state, enables the examination of fluorescence light in a defined wavelength range of a first dye, for example, 5-ALA, excited to fluoresce in the surgical region and/or the examination of autofluorescence in the defined wavelength range of biological tissue and/or objects in the surgical region. Here, the endoscope is configured in such a way that, in a first endoscope operating state, the examination of white light scattered in the surgical region and, in a further endoscope operating state differing from the first operating state, the examination of fluorescence light in the defined wavelength range of the first dye, for example, 5-ALA, excited to fluoresce in the surgical region and/or the examination of autofluorescence light in the defined wavelength range of biological tissue and/or objects in the surgical region is possible. The further endoscope operating state and the further surgical microscope operating state are therefore matched to one another. Here, the surgical microscope and the endoscope are preferably operably coupled to one another in such a way that the further surgical microscope operating state is set automatically, that is, triggered by setting the further endoscope operating state, when the further endoscope operating state is set.

It is moreover a concept of the invention to provide in the visualization system a device for automatically operably coupling the surgical microscope and the first endoscope when the endoscope is activated and/or when the endoscope is picked up by the observing person and/or when a portion of the endoscope is arranged in an observation region of the surgical microscope and/or when fluorescence light and/or autofluorescence light in the defined wavelength range occurs.

According to the invention, it is also proposed that there is a further endoscope in the visualization system, which further endoscope, in at least one endoscope operating state, enables the examination of fluorescence light in a defined further wavelength range of a further dye, for example, NaFl, excited to fluoresce in the surgical region and/or the examination of autofluorescence light in the defined further wavelength range of biological tissue and/or objects in the surgical region, wherein the surgical microscope, in a further surgical microscope operating state differing from the first operating state, enables the examination of fluorescence light in the defined wavelength range of the further dye, for example, NaFl, excited to fluoresce in the surgical region and/or the examination of autofluorescence in the defined wavelength range of biological tissue and/or objects in the surgical region, and wherein the surgical microscope and the endoscope are operably coupleable in such a way that, when the endoscope is operated in this further endoscope operating state, the further surgical microscope operating state is set automatically. Here, a concept of the invention is, in particular, that the device for automatically operably coupling the surgical microscope and the further endoscope is effected automatically, that is, triggered by receiving the further endoscope and/or arranging a portion of the further endoscope in the observation region and/or by the occurrence of fluorescence light and/or autofluorescence light, when the further endoscope is activated and/or when the further endoscope is picked up by the observing person and/or when a portion of the further endoscope is arranged in an observation region of the surgical microscope and/or when fluorescence light and/or autofluorescence light in the defined wavelength range occurs.

In particular, provision can also be made of a further endoscope in the visualization system, which further endoscope, in at least one endoscope operating state, enables the examination of fluorescence light in a defined further wavelength range of a further dye, for example, ICG, excited to fluoresce in the surgical region and/or the examination of autofluorescence light in the defined further wavelength range of biological tissue and/or objects in the surgical region, wherein the surgical microscope, in a further surgical microscope operating state differing from the first operating state, enables the examination of fluorescence light in the defined further wavelength range of the further dye, for example, ICG, excited to fluoresce in the surgical region and/or the examination of autofluorescence in the defined wavelength range of biological tissue and/or objects in the surgical region, and wherein the surgical microscope and the endoscope are operably coupleable in such a way that, when the endoscope is operated in this endoscope operating state, the further surgical microscope operating state is set automatically.

Here, in turn, a concept of the invention is the automatic operable coupling of the surgical microscope and the further endoscope when the further endoscope is activated and/or when the further endoscope is picked up by the observing person and/or when a portion of the further endoscope is arranged in an observation region of the surgical microscope and/or when fluorescence light and/or autofluorescence light in the defined further wavelength range occurs.

In the visualization system according to the invention, the at least one endoscope can be embodied, in particular, as a video endoscope.

Moreover, it is proposed that the visualization system also has a device for rotating an endoscopic image of the surgical region displayed at the display relative to the display.

In a method according to the invention for operating a visualization system, which contains a surgical microscope for observing an operation system with magnification and which has a device for acquiring endoscopic image data in the surgical region, which is operably coupled to the surgical microscope for displaying the endoscopic image data, at least one operating parameter of the surgical microscope is modified when adjusting at least one operating parameter of the video endoscope and/or at least one operating parameter of the video endoscope is varied when adjusting at least one operating parameter of the surgical microscope.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described with reference to the drawings wherein:

FIG. 1 shows a first visualization system with a surgical microscope and with a device for acquiring endoscopic image data with a first, second and third video endoscope;

FIG. 2 is a section view through the first video endoscope in the device for acquiring electronic image data;

FIG. 3 shows the configuration of the surgical microscope in the surgical visualization system;

FIG. 4 shows a filter wheel of an illumination system in the surgical microscope;

FIG. 5 shows a filter wheel arranged in an observation beam path of the surgical microscope;

FIG. 6A and FIG. 6B, as well as FIG. 6C and FIG. 6D, show different displays at a display of the surgical microscope; and

FIG. 6E shows a full screen observation image of the video endoscope; and,

FIG. 7 shows a further visualization system with an surgical microscope and with a device for acquiring endoscopic image data with a first, second and third video endoscope.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

The visualization system 10 shown in FIG. 1 is a surgical visualization system. It includes a surgical microscope 12 with a microscope unit 16 accommodated on a stand 14 and with a console terminal 18, which contains a computer unit 19 with a touch-sensitive display 20. The surgical microscope 12 enables for a viewing person the stereoscopic observation of a surgical region 22 in a binocular viewing unit 24. The viewing unit 24 has eyepieces (102, 104) with left-hand and right-hand optical observation beam paths (26 a, 26 b), which pass through a common microscope main objective 28.

In the visualization system 10 there is a device 30 for acquiring endoscopic image data. The device 30 contains a first, second and third video endoscope (32, 34, 36). The video endoscope 32 allows the examination of the surgical region 22 by acquiring white light scattered in the surgical region 22 and the fluorescence light of the dye 5-ALA excited to fluoresce in the surgical region 22.

The video endoscope 34 serves the examination of the surgical region 22 by acquiring white light scattered in the surgical region 22 and the fluorescence light of the dye sodium fluorescein (NaFl) excited to fluoresce.

The video endoscope 36 is suitable for examining the surgical region 22 by acquiring white light scattered in the surgical region 22 and the fluorescence light of the dye indocyanine green (ICG) excited to fluoresce in the surgical region 22.

The touch-sensitive display 20 of the surgical microscope 12 renders possible, firstly, the control and adjustment of optical imaging parameters of the microscope unit 16 and of the video endoscopes 32, 34, and 36 and, secondly, the separate or simultaneous visualization of the object region 22 observed by means of a video endoscope (32, 34, 36) or by means of the microscope unit 16.

FIG. 2 shows the configuration of the first video endoscope 32 from FIG. 1. The video endoscope 32 has an endoscope body 39, extended in the longitudinal direction 37, with a handle 38 connected thereto, with an electrical energy store 41 being arranged in the handle. The electrical energy store 41 is a battery. However, in principle, it also is possible to provide a high-performance capacitor as an electrical energy store 41. The video endoscope 32 enables the observation of the object region 46 in a white-light operating mode and in a fluorescence-light operating mode. To this end, the video endoscope 32 contains viewing optics 40, which have an objective assembly 42 and includes an optical transfer system 44 with a folding mirror 45 so as to selectively feed an image of an surgical region 22 to an image sensor 48 sensitive to infrared light and to an image sensor 50 sensitive to light in the visible spectral range.

In order to illuminate the surgical region 22, there is, in the video endoscope 32, an illumination system 52 with a white-light LED 54 and with a light source 56 providing a light with which the fluorescent dye can be excited to fluoresce in a narrow bandwidth. To this end, the illumination system 52 contains an optical waveguide 58 and it has a switchable folding mirror 60, which renders it possible to illuminate the object region 46 selectively with the light from the white-light LED 54 or the light from the light source 56. In order to be able to suppress the fluorescence light emanating from fluorescent objects, for example, the dye ICG, which is scattered in the surgical region 22 and which reaches the transfer system 44 by way of the objective assembly 42, there is a switchable emission filter 64 in the video endoscope 32. The emission filter 64 can selectively be moved into, and out of, the optical imaging beam path 62.

The video endoscope 32 contains an activation circuit 66, which is arranged in the endoscope body 39. The activation circuit 66 has a touch sensor 68 integrated into the handle 38 as an activation sensor, by means of which it is possible to detect the video endoscope 32 being picked up by the hand of an observing person at the handle 38 in order then to bring the video endoscope 32 into a work mode from a rest mode. In this case, the activation circuit 66 effects automatic operable coupling of the video endoscope 32 and the surgical microscope 12. The video endoscope 32 is registered at the computer unit 19 of the surgical microscope 12 by means of the activation circuit 66. It then transmits to the computer unit 19 in a wireless fashion electronic image data which can be displayed at the touch-sensitive display 20 of the surgical microscope 12.

If an observing person releases the handle 38 from the hand, this is detected by means of the touch sensor 68. The activation circuit 66 then brings the video endoscope 32 back into the rest mode. In this way, the electrical energy consumption of the video endoscope 32 can be minimized when the latter is merely provided but not used.

The configuration of the second video endoscope 34 and of the third video endoscope 36 from FIG. 1 corresponds, in principle, to the configuration of the first video endoscope 32. However, in this case, in addition to the white-light LED, the second video endoscope 34 and the third video endoscope 36 each contain a light source and an emission filter which are tuned to the excitation and detection of fluorescence light from the dye 5-ALA or NaFl. Here too, there is an activation circuit with a touch sensor, which has the functionality described above.

FIG. 3 explains the configuration of the microscope unit 16 of the surgical microscope 12 in the visualization system 10. The microscope unit 16 enables a stereoscopic observation of the surgical region 22 with viewing beam paths (70, 72) which pass through a microscope main objective 74. A zoom system (76, 78) is provided in the microscope unit 16 for setting the magnification in the viewing beam paths (70, 72). There is an illumination system 80 with a light source 82 in the microscope unit 16 for illuminating the surgical region 22 with illumination light.

The light emitted by the light source 82 is collimated by collimation optics 84 in the plane of an illumination field diaphragm 86 and guided into the surgical region 22 via the condenser lens 88 and the microscope main objective 28 by way of the illumination beam path 92. The illumination system 80 contains an adjustable filter wheel 94, which is adjustable by means of a drive 95 and which has different filters for setting the spectral composition of the illumination light guided to the surgical region 22.

FIG. 4 shows a plan view of the filter wheel 94. The filter wheel 94 has a pinhole diaphragm 96 d and illumination filter (96 a, 96 b, 96 c), by means of which it is possible to set the spectral composition of the illumination light in such a way that the dye ICG or 5-ALA or NaFl can be excited therewith to fluoresce and the light with a wavelength corresponding to the wavelength of the fluorescence light of these dyes being filtered in the process.

There is in each case one adjustable filter wheel 112 in the left-hand and right-hand viewing beam path (70, 72) of the microscope unit 16. FIG. 5 shows a plan view of the filter wheel 112. The filter wheel 112 contains the filters (116 a, 116 b, 116 c) and a pinhole diaphragm 116 d. The transmission characteristic of the filters (116 a, 116 b, 116 c) is matched to the transmission characteristic of the illumination filters (96 a, 96 b, 96 c). The filters (116 a, 116 b, 116 c) are used to suppress the light exciting the fluorescence of the dye ICG or 5-ALA or NaFl and pass the light with a wavelength of the fluorescence light of these dyes.

In order to visualize in the surgical region 22 by means of fluorescence light tissue structures in which the dye 5-ALA has accumulated, the filter 96 a of the filter wheel 94 is switched into the illumination beam path 92 and the filter 116 a of the filter wheel 112 is arranged in the left-hand and right-hand viewing beam path (70, 72). Accordingly, in order to visualize tissue structures in the surgical region 22 in which the dye ICG has accumulated, the filter 96 b is arranged in the illumination beam path 92 and the filter 116 b of the corresponding filter wheel 112 is positioned in the left-hand and right-hand viewing beam path (70, 72). In order to visualize tissue structures containing the dye NaFl, the filter 96 c is switched into the illumination beam path 92 and the filter 116 c of the filter wheel 112 is positioned in the left-hand and right-hand viewing beam path (70, 72).

In the microscope unit 16 there is a camera 108 for acquiring IR light and a camera 110, by means of which fluorescence light in the visual spectral range can be detected. The camera 108 and the camera 110 are connected to the computer unit 19 of the surgical microscope 12 shown in FIG. 1.

FIG. 6A shows a display 118 of the display 20 triggered by activating a video endoscope (32, 34, 36). This informs an observing person about which one of the video endoscopes is currently used to conduct work.

FIG. 6B shows a display 118 of the display 20 with control buttons for controlling an activated video endoscope (32, 34, 36). The control button 123 allows an operator in the correspondingly activated video endoscope (32, 34, 36) to switch between the operating mode for observing the surgical region 22 by means of white light and the operating mode for viewing the surgical region 22 by capturing fluorescence light. Here, the operating mode of the microscope unit 16 is also switched from a white-light operating mode to the fluorescence-light operating mode, and vice versa, when a video endoscope (32, 34, 36) is switched between the white-light operating mode and the fluorescence-light operating mode by means of the corresponding activation circuit. This measure causes the operating state of the surgical microscope 12 to always automatically be matched to the operating state of the employed video endoscope (32, 34, 36) in the visualization system 10.

FIG. 6C and FIG. 6D each show an observation image from a video endoscope (32, 34, 36) and an observation image from the microscope unit 16 at the display 20. Here, the observation image from the video endoscope (32, 34, 36) and from the microscope unit 16 is visualized in two mutually separated fields (124, 126), which have different dimensions. By touching the corresponding smaller field 126, an observing person in this case can selectively cause the observation image from the microscope unit 16 or from the selected video endoscope (32, 34, 36) to be displayed in the larger field 124.

Optionally, provision can also be made in the visualization system for the observation image of a corresponding video endoscope (32, 34, 36) to be brought automatically to the display in the larger field 124, triggered by picking up or switching on the specific video endoscope (32, 34, 36) by an observing person. That is, in this case, the activation sensor 68 for a video endoscope (32, 34, 36) is integrated into the surgical microscope 12 and the activation circuit 66 is situated partly in the surgical microscope 12 and partly in a video endoscope (32, 34, 36) in each case.

FIG. 6E shows a full screen 128 observation image of the video endoscope (32, 34, 36). An observing person can rotate this full screen 128 by virtue of wiping the fingers of a hand over the display 20 in a manner following a direction of rotation or by virtue of touching a desired rotational position of the image (128, 128′) with the fingers of a hand at the display 20.

It should be noted that, in an alternative embodiment of the surgical visualization sensor, a video endoscope (32, 34, 36) may also have a gyro sensor instead of a touch sensor as an activation sensor in the activation circuit 66, which gyro sensor switches the corresponding video endoscope (32, 34, 36) into a work state when detecting a displacement thereof. As an alternative thereto, it is also possible to provide a Hall sensor in the activation circuit, by means of which it is possible to detect whether the corresponding video endoscope (32, 34, 36) is moved out of a rest position in which the video endoscope (32, 34, 36), in the portion of the Hall sensor, is exposed to a defined magnetic field. Moreover, it should be noted that, in order to switch a video endoscope from a rest state into a work state, provision can also be made in the activation circuit 66 for a speech sensor as activation sensor instead of the aforementioned sensors.

FIG. 7 shows a further visualization system 10′ with an surgical microscope 12 and with a device for acquiring electronic image data with a first, a second and a third video endoscope (32′, 34′, 36′). To the extent that the assemblies of the visualization system 10′ and elements in FIG. 7 correspond to elements and assemblies from the preceding figures, these are identified by the same numbers as reference signs. In order to connect the video endoscopes (32′, 34′, 36′) to the surgical microscope 12, provision is made here for a cable 130 with a plug 132 and a socket 134 formed in the console terminal 18 of the surgical microscope 12. Plugging the plug 132 into the socket 134 in this case actuates an activation circuit arranged in the corresponding video endoscope (32′, 34′, 36′), which activation circuit, when activated, causes the corresponding video endoscope (32′, 34′, 36′) to be registered by the computer unit 19 of the surgical microscope 12 and sets a work operating mode for the corresponding video endoscope (32′, 34′, 36′). A consequence of this measure then is the display of the operating parameters of the corresponding video endoscope (32′, 34′, 36′) at the display 20 and it therefore enables a display of the observation image thereof. Conversely, if the plug-in connection between video endoscope (32′, 34′, 36′) and surgical microscope 12 is opened, the consequence thereof is a deregistration of the corresponding video endoscope (32′, 34′, 36′) at the surgical microscope 12 and the corresponding video endoscope is put into a rest mode.

In conclusion, the following, in particular, should be registered: The invention relates to a visualization system (10, 10′) with a surgical microscope 12 for observing a surgical region 22 with magnification, having a computer unit 19 with a display 20 for displaying image data. The visualization system (10, 10′) comprises a device 30 for acquiring endoscopic image data in the surgical region 22, which is operably coupled to the surgical microscope 12 for displaying the endoscopic image data. The device 30 for acquiring endoscopic image data in the surgical region 22 contains a circuit 66 which is configured for acquiring actuation information and actuatable by an observing person, the circuit setting a surgical microscope operating state matched to the device 30 for acquiring endoscopic images in the surgical region 22 when the actuation information for the surgical microscope 12 is present.

It is understood that the foregoing description is that of the preferred embodiments of the invention and that various changes and modifications may be made thereto without departing from the spirit and scope of the invention as defined in the appended claims.

LIST OF REFERENCE SIGNS

-   10, 10′ Visualization system -   12 Surgical microscope -   14 Stand -   16 Microscope unit -   18 Console terminal -   19 Computer unit -   20 Display -   22 Surgical region -   24 Binocular viewing unit -   26 a, 26 b Observation beam path -   28 Microscope main objective -   30 Device for acquiring endoscopic image data -   32, 32′, 32″, 34, 34′, 36, 36′ Video endoscope -   37 Longitudinal direction -   38 Handle -   39 Endoscope body -   40 Viewing optics -   41 Electrical energy store -   42 Objective assembly -   44 Optical transfer system -   45 Folding mirror -   46 Object region -   48, 50 Image sensor -   52 Illumination system -   54 White-light LED -   56 Light source -   58 Optical waveguide -   60 Folding mirror -   62 Imaging beam path -   64 Emission filter -   66 Activation circuit -   68 Touch sensor -   70, 72 Viewing beam path -   74 Microscope main objective -   76, 78 Zoom system -   80 Illumination system -   82 Light source -   84 Collimation optics -   86 Illumination field diaphragm -   88 Condenser lens -   92 Illumination beam path -   94 Filter wheel -   95 Drive -   96 a, 96 b, 96 c Filter -   96 d Pinhole diaphragm -   102, 104 Eyepiece -   108, 110 Camera -   112 Filter wheel -   116 a, 116 b, 116 c Filter -   116 d Pinhole diaphragm -   118 Display -   123 Control button -   124, 126 Field -   128, 128′ Image -   130 Cable -   132 Plug -   134 Socket 

What is claimed is:
 1. A visualization system comprising: a surgical microscope assembly for viewing a surgical region under magnification; said surgical microscope assembly including a computer unit having a display for displaying image data; a detection arrangement configured to detect endoscopic images in the surgical region and being operatively coupled to said surgical microscope assembly; a circuit actuable by a viewing person and said circuit being configured to detect actuation data; and, said circuit being configured to set an operating state of said surgical microscope assembly matched to said detection arrangement in response to a presence of said actuation data for said surgical microscope assembly.
 2. The visualization system of claim 1, wherein said circuit is an activation switching circuit configured to transfer said detecting arrangement from a rest state into an activation state; and, said activation switching circuit includes an activation sensor selected from the group including a gyro sensor, hall sensor or voice sensor.
 3. The visualization system of claim 2, wherein said detection arrangement includes an endoscope.
 4. The visualization system of claim 3, wherein said endoscope has an endoscope body wherein said activation sensor is mounted.
 5. The visualization system of claim 4, wherein said endoscope of said detection arrangement defines a first operating state wherein white light, which is scattered in the surgical region, can be examined and a second operating state wherein fluorescence light can be examined in a defined wavelength range of a dye (5-ALA, NaFl, ICG), which is excited to fluorescence in the surgical region, and/or autofluorescence light can be examined in the defined wavelength range of biological tissue and/or objects in the surgical region.
 6. The visualization system of claim 3, wherein said activation sensor is mounted in said surgical microscope.
 7. The visualization system of claim 6, wherein said endoscope of said detection arrangement defines a first operating state wherein white light, which is scattered in the surgical region, can be examined and a second operating state wherein fluorescence light can be examined in a defined wavelength range of a dye (5-ALA, NaFl, ICG), which is excited to fluorescence in the surgical region, and/or autofluorescence light can be examined in the defined wavelength range of biological tissue and/or objects in the surgical region.
 8. The visualization system of claim 3, wherein said surgical microscope assembly has a first operating state wherein white light, which is scattered in the surgical region, can be examined; and, a second operating state, different from said first operating state, wherein fluorescence light can be examined in a defined wavelength range of a first dye (5-ALA), which is excited to fluorescence in the surgical region, and/or the examination of autofluorescence light in the defined wavelength range of biological tissue and/or objects in the surgical region; said endoscope permits, in a first endoscope operating state, the examination of fluorescence light in the defined wavelength range of the first dye (5-ALA) in the surgical region, the dye being excited to fluorescence, and/or the examination of autofluorescence light in the defined wavelength range of biological tissue in the surgical region; and, wherein said surgical microscope assembly and said endoscope are operatively couplable so that when the endoscope is in this endoscope operating state, the other operating state of the surgical microscope assembly is automatically terminated.
 9. The visualization system of claim 8, wherein said system further comprises a coupling unit for automatically operatively coupling said surgical microscope assembly and said first endoscope when said endoscope is activated and/or when said endoscope is taken up by an operator and/or when there is a command of a section of said endoscope in a viewing region of said surgical microscope assembly and/or when there is an occurrence of fluorescence light and/or autofluorescence light in the defined wavelength range.
 10. The visualization system of claim 9, wherein said endoscope is a first endoscope; and, wherein said detection arrangement comprises a second endoscope which, in a second endoscopic operating state, permits the examination of fluorescence light in a defined further wavelength range of a further dye (NaFl), which is excited to fluorescence, in the surgery region and/or which permits the examination of autofluorescence light in the defined further wavelength range of biological tissue in the surgical region; said operating state of said surgical microscope assembly is a first operating state; said surgical microscope assembly has a second operating state different from said first operating state thereof which permits the examination of fluorescence light in the defined further wavelength range of an additional dye (NaFl), which is excited to fluorescence, in the surgical region, and/or the examination of an autofluorescence light in the defined further wavelength range of biological tissue and/or objects in the surgery region; and, wherein the surgical microscope assembly and said second endoscope are operatively couplable so that the second operating state of the surgical microscope assembly is automatically terminated when there is an operation of the second endoscope in the second endoscope operating state.
 11. The visualization system of claim 10, wherein said system further comprises a coupling unit for automatically operatively coupling the surgical microscope assembly and the second endoscope when there is an activation of the second endoscope and/or when a viewing person takes up the second endoscope and/or when there is a command of a section of the second endoscope in a viewing region of the surgical microscope assembly and/or when there is an occurrence of fluorescence light and/or autofluorescence light in the defined further wavelength range.
 12. The visualization system of claim 11, wherein said detection arrangement includes a third endoscope which permits, in an endoscopic operating state, the examination of fluorescence light in a defined further wavelength range of a further dye (ICG), which is excited to fluorescence, in the surgical region and/or the examination of autofluorescence in the defined further wavelength range of biological tissue and/or objects in the surgical region; wherein the surgical microscope assembly permits, in a second operating state thereof different from the first operating state thereof, the examination of fluorescence light in the defined further wavelength of the dye (ICG), which is excited to fluorescence, in the surgical region and/or the examination of an autofluorescence light in the defined wavelength range of biological tissue and/or objects in the surgical region; and, the surgical microscope assembly and the third endoscope are operatively couplable so that, when operating the third endoscope in this further endoscope operating state, the additional operating state of the surgical microscope assembly is automatically terminated.
 13. The visualization system of claim 12, wherein said system further comprises a coupling unit for automatically operatively coupling the surgical microscope assembly and the third endoscope where there is an activation of the third endoscope and/or when taking up the third endoscope by a viewing person and/or when there is a command of a section of the third endoscope in a viewing region of the surgical microscope assembly and/or when there is an occurrence of fluorescence light and/or autofluorescence light in the defined further wavelength range.
 14. The visualization system of claim 13, wherein at least one of the endoscopes is configured as a video endoscope.
 15. The visualization system of claim 12, wherein said system further comprises a unit configured to rotate an endoscopic image, which is shown on the display and is from the surgical region, relative to the display.
 16. A method of operating a visualization system which includes: a surgical microscope assembly for viewing a surgical region under magnification; and, a detection arrangement configured to detect endoscopic images in the surgical region and being operatively coupled to said surgical microscope assembly; the method comprising the steps of: changing at least one operating parameter of the surgical microscope assembly in response to a shifting of at least one operating parameter of a video endoscope; and/or, changing at least one operating parameter of the video endoscope in response to a shifting of at least one operating parameter of the surgical microscope assembly. 